pix_convolve.cpp 22.6 KB
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////////////////////////////////////////////////////////
//
// GEM - Graphics Environment for Multimedia
//
// zmoelnig@iem.kug.ac.at
//
// Implementation file
//
//    Copyright (c) 1997-1998 Mark Danks.
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//    Copyright (c) Günther Geiger.
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//    Copyright (c) 2001-2011 IOhannes m zmölnig. forum::für::umläute. IEM. zmoelnig@iem.at
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//    Copyright (c) 2002 James Tittle & Chris Clepper
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//    For information on usage and redistribution, and for a DISCLAIMER OF ALL
//    WARRANTIES, see the file, "GEM.LICENSE.TERMS" in this distribution.
//
/////////////////////////////////////////////////////////

#include "pix_convolve.h"
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#include "Gem/Exception.h"
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#include "Utils/Functions.h"
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CPPEXTERN_NEW_WITH_TWO_ARGS(pix_convolve, t_floatarg, A_DEFFLOAT, t_floatarg, A_DEFFLOAT);
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/////////////////////////////////////////////////////////
//
// pix_convolve
//
/////////////////////////////////////////////////////////
// Constructor
//
/////////////////////////////////////////////////////////
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pix_convolve :: pix_convolve(t_floatarg fRow, t_floatarg fCol) :
  m_imatrix(NULL),
  m_irange(255),
  m_rows(0), m_cols(0),
  m_chroma(0)
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{
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  int row = static_cast<int>(fRow);
  int col = static_cast<int>(fCol);
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  if (!row || !col ) {
    throw(GemException("matrix must have some dimension"));
  }
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  if (!(row % 2) || !(col % 2) ) {
    throw(GemException("matrix must have odd dimensions"));
  }
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  m_rows = row;
  m_cols = col;
  m_imatrix = new signed short[m_rows * m_cols];
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  // zero out the matrix
  int i;
  for (i = 0; i < m_cols * m_rows; i++) {
    m_imatrix[i] = 0;
  }
  // insert a one for the default center value (identity matrix)
  m_imatrix[ ((m_cols / 2 + 1) * m_rows) + (m_rows / 2 + 1) ] = 255;
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  inlet_new(this->x_obj, &this->x_obj->ob_pd, gensym("float"), gensym("ft1"));
  inlet_new(this->x_obj, &this->x_obj->ob_pd, gensym("list"), gensym("matrix"));
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}

/////////////////////////////////////////////////////////
// Destructor
//
/////////////////////////////////////////////////////////
pix_convolve :: ~pix_convolve()
{
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  if (m_imatrix) {
    delete [] m_imatrix;
  }
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}

/////////////////////////////////////////////////////////
// processImage
//
/////////////////////////////////////////////////////////
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void pix_convolve :: calculateRGBA3x3(imageStruct &image,imageStruct &tempImg)
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{
  int i;
  int j;
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//  int k;
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  int xsize =  tempImg.xsize;
  int ysize =  tempImg.ysize;
  int size = xsize*ysize - xsize-1;
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  int csize = tempImg.csize;
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  int* src = (int*) tempImg.data;
  int* dest = (int*)image.data;
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//unroll this to do R G B in one pass?? (too many registers?)
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  i = xsize;
  int* val1 = 0;
  int* val2 = src+i-xsize;
  int* val3 = src+i-xsize+1;
  int* val4 = src+i-1;
  int* val5 = src+i;
  int* val6 = src+i+1;
  int* val7 = src+i+xsize-1;
  int* val8 = src+i+xsize;
  int* val9 = src+i+xsize+1;
  int res;
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  for (i=xsize+1; i<size; i++) {
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    val1 = val2;
    val2 = val3;
    val3 = src+i-xsize+1;
    val4 = val5;
    val5 = val6;
    val6 = src+i+1;
    val7 = val8;
    val8 = val9;
    val9 = src+i+xsize+1;
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    if (i%xsize == 0 || i%xsize == xsize-1) {
      continue;
    }
#ifndef __APPLE__
    for (j=0; j<3; j++)
#else
    for (j=1; j<4; j++)
#endif
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    {
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      //      res =  m_imatrix[0]*(int)((unsigned char*)val1)[j];
      res =  m_imatrix[0]*static_cast<int>(reinterpret_cast<unsigned char*>(val1)[j]);
      res += m_imatrix[1]*static_cast<int>(reinterpret_cast<unsigned char*>(val2)[j]);
      res += m_imatrix[2]*static_cast<int>(reinterpret_cast<unsigned char*>(val3)[j]);
      res += m_imatrix[3]*static_cast<int>(reinterpret_cast<unsigned char*>(val4)[j]);
      res += m_imatrix[4]*static_cast<int>(reinterpret_cast<unsigned char*>(val5)[j]);
      res += m_imatrix[5]*static_cast<int>(reinterpret_cast<unsigned char*>(val6)[j]);
      res += m_imatrix[6]*static_cast<int>(reinterpret_cast<unsigned char*>(val7)[j]);
      res += m_imatrix[7]*static_cast<int>(reinterpret_cast<unsigned char*>(val8)[j]);
      res += m_imatrix[8]*static_cast<int>(reinterpret_cast<unsigned char*>(val9)[j]);
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      res*=m_irange;
      res>>=16;
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      ((unsigned char*)dest)[i*csize+j] = CLAMP(res);
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    }

  }

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}

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void pix_convolve :: processRGBAImage(imageStruct &image)
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{
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  image.copy2Image(&tempImg);
  int initX = m_rows / 2;
  int initY = m_cols / 2;
  int maxX = tempImg.xsize - initX;
  int maxY = tempImg.ysize - initY;
  int xTimesc = tempImg.xsize * tempImg.csize;
  int initOffset = initY * xTimesc + initX * tempImg.csize;
  const int csize = tempImg.csize;

  if (m_rows == 3 && m_cols == 3) {
    calculateRGBA3x3(image,tempImg);
    return;
  }
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  for (int y = initY; y < maxY; y++) {
    int realY = y * xTimesc;
    int offsetY = realY - initOffset;
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    for (int x = initX; x < maxX; x++) {
      int realPos = x * csize + realY;
      int offsetXY = x * csize + offsetY;
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      // skip the alpha value
      for (int c = 1; c < csize; c++) {
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        int new_val = 0;
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        int offsetXYC = offsetXY + c;
        for (int matY = 0; matY < m_cols; matY++) {
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          int offsetXYCMat = matY * xTimesc + offsetXYC;
          int realMatY = matY * m_rows;
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          for (int matX = 0; matX < m_rows; matX++) {
            new_val += (tempImg.data[offsetXYCMat + matX * csize] *
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                        m_imatrix[realMatY + matX])>>8;
          }
        }
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        image.data[realPos + c] = CLAMP(new_val);
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        //removes insult from injury ??
        // we do not use the m_irange anymore ...  remove it ??
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      }
    }
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  }

}

void pix_convolve :: processGrayImage(imageStruct &image)
{
  const int csize=image.csize;
  image.copy2Image(&tempImg);
  int initX = m_rows / 2;
  int initY = m_cols / 2;
  int maxX = tempImg.xsize - initX;
  int maxY = tempImg.ysize - initY;
  int xTimesc = tempImg.xsize * csize;
  int initOffset = initY * xTimesc + initX * csize;

  for (int y = initY; y < maxY; y++)    {
    int realY = y * xTimesc;
    int offsetY = realY - initOffset;

    for (int x = initX; x < maxX; x++)        {
      int offsetXY = x + offsetY;

      int new_val = 0;
      int offsetXYC = offsetXY;
      for (int matY = 0; matY < m_cols; matY++)   {
        int offsetXYCMat = matY * xTimesc + offsetXYC;
        int realMatY = matY * m_rows;
        for (int matX = 0; matX < m_rows; matX++)     {
          new_val += (tempImg.data[offsetXYCMat + matX] *
                      m_imatrix[realMatY + matX])>>8;
        }
      }
      image.data[x+realY] = CLAMP(new_val);
      //removes insult from injury ??
      // we do not use the m_irange anymore ...  remove it ??
    }
  }
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}
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void pix_convolve :: processYUVImage(imageStruct &image)
{
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  image.copy2Image(&tempImg);
  //float range = 1;
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  int initX = m_rows / 2;
  int initY = m_cols / 2;
  int maxX = tempImg.xsize - initX;
  int maxY = tempImg.ysize - initY;
  int xTimesc = tempImg.xsize * tempImg.csize;
  int initOffset = initY * xTimesc + initX * tempImg.csize;
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//   calculate3x3YUV(image,tempImg);
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//quick fix for Intel 3x3YUV problems
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#ifdef __BIG_ENDIAN__
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  if (m_rows == 3 && m_cols == 3) {
    calculate3x3YUV(image,tempImg);
    return;
  }
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#endif
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  if (m_chroma) {
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    for (int y = initY; y < maxY; y++)   {
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      int realY = y * xTimesc;
      int offsetY = realY - initOffset;

      for (int x = initX; x < maxX; x++) {
        int realPos = x * tempImg.csize + realY;
        int offsetXY = x * tempImg.csize + offsetY;

        // skip the UV
        for (int c = 1; c < 3; c+=2) {
          int new_val = 0;
          int offsetXYC = offsetXY + c;
          for (int matY = 0; matY < m_cols; matY++) {
            int offsetXYCMat = matY * xTimesc + offsetXYC;
            int realMatY = matY * m_rows;
            for (int matX = 0; matX < m_rows; matX++) {
              new_val += (tempImg.data[offsetXYCMat + matX * tempImg.csize] *
                          m_imatrix[realMatY + matX])>>8;
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            }
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          }
          image.data[realPos + c] = CLAMP(new_val);
          // image.data[realPos + c-1] = 128;  //remove the U+V
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        }
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      }
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    }
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  } else {
    for (int y = initY; y < maxY; y++) {
      int realY = y * xTimesc;
      int offsetY = realY - initOffset;

      for (int x = initX; x < maxX; x++) {
        int realPos = x * tempImg.csize + realY;
        int offsetXY = x * tempImg.csize + offsetY;

        // skip the UV
        for (int c = 1; c < 3; c+=2) {
          int new_val = 0;
          int offsetXYC = offsetXY + c;
          for (int matY = 0; matY < m_cols; matY++) {
            int offsetXYCMat = matY * xTimesc + offsetXYC;
            int realMatY = matY * m_rows;
            for (int matX = 0; matX < m_rows; matX++) {
              new_val += (tempImg.data[offsetXYCMat + matX * tempImg.csize] *
                          m_imatrix[realMatY + matX])>>8;
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            }
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          }
          image.data[realPos + c] = CLAMP(new_val);
          image.data[realPos + c-1] = 128;  //remove the U+V
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        }
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      }
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    }
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  }
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}
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//make two functions - one for chroma one without
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void pix_convolve :: calculate3x3YUV(imageStruct &image,imageStruct &tempImg)
{
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#ifdef __VEC__
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  calculate3x3YUVAltivec(image,tempImg);
  return;
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#else

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  int i;
  int j;
  int k;
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  int xsize =  tempImg.xsize -1;
  int ysize =  tempImg.ysize -1;
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  int size = xsize*ysize - xsize-1;
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  int length;
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  short* src = (short*) tempImg.data;
  short* dest = (short*)image.data;
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  register int mat1,mat2,mat3,mat4,mat5,mat6,mat7,mat8,mat9;
  register int res1,res2,res3,res4,res5,res6,res7,res8,res9;
  register int range;
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  mat1 = m_imatrix[0];
  mat2 = m_imatrix[1];
  mat3 = m_imatrix[2];
  mat4 = m_imatrix[3];
  mat5 = m_imatrix[4];
  mat6 = m_imatrix[5];
  mat7 = m_imatrix[6];
  mat8 = m_imatrix[7];
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  mat9 = m_imatrix[8];
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  range =m_irange;
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  if (m_chroma) {
    i = xsize;
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#ifdef i386
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    register unsigned char val1 = 0;
    register unsigned char val2 = src[i-xsize+1];
    register unsigned char val3 = src[i-xsize+3];
    register unsigned char val4 = src[i-1];
    register unsigned char val5 = src[i+1];
    register unsigned char val6 = src[i+3];
    register unsigned char val7 = src[i+xsize-1];
    register unsigned char val8 = src[i+xsize+1];
    register unsigned char val9 = src[i+xsize+3];
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#else
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    register unsigned char val1 = 0;
    register unsigned char val2 = src[i-xsize+1];
    register unsigned char val3 = src[i-xsize+3];
    register unsigned char val4 = src[i-1];
    register unsigned char val5 = src[i+1];
    register unsigned char val6 = src[i+3];
    register unsigned char val7 = src[i+xsize-1];
    register unsigned char val8 = src[i+xsize+1];
    register unsigned char val9 = src[i+xsize+3];
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#endif
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    //unroll this 2x to fill the registers? (matrix*y1*y2= 9*9*9 =27)
    //messed up looking on x86
    i=xsize+2;

    for (k=1; k<ysize; k++) {
      for (j=1; j<xsize; j++) {
        //load furthest value first...the rest should be in cache

        val7 = val8;
        val8 = val9;
        val9 = src[i+xsize+3]; //this will come from main mem
        val1 = val2;
        val2 = val3;
        val3 = src[i-xsize+3]; //should be in cache from previous pass
        val4 = val5;
        val5 = val6;
        val6 = src[i+3];

        //unroll??
        res1 = mat1*static_cast<int>(val1);
        res2 = mat2*static_cast<int>(val2);
        res3 = mat3*static_cast<int>(val3);
        res4 = mat4*static_cast<int>(val4);
        res5 = mat5*static_cast<int>(val5);
        res6 = mat6*static_cast<int>(val6);
        res7 = mat7*static_cast<int>(val7);
        res8 = mat8*static_cast<int>(val8);
        res9 = mat9*static_cast<int>(val9);


        res1 += res2 + res3;
        res4 += res5 + res6;
        res7 += res8 + res9;
        res1 += res4 + res7;

        res1*=range;
        res1>>=16;
        ((unsigned char*)dest)[i*2+1] = CLAMP(res1);
        i++;
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      }
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      i=k*tempImg.xsize;
    }
  } else {

    i = xsize;
    //make these temp register vars rather than pointers?

    short* val1 = 0;
    short* val2 = src+i-xsize; //val2 = src[i-xsize];
    short* val3 = src+i-xsize+1; //val3 = src[i-xsize+1];
    short* val4 = src+i-1; //val4 = src[i-1];
    short* val5 = src+i; //val5 = src[i];
    short* val6 = src+i+1; //val6 = src[i+1];
    short* val7 = src+i+xsize-1; //val7 = src[i+xsize-1];
    short* val8 = src+i+xsize; //val8 = src[i+xsize];
    short* val9 = src+i+xsize+1; //val9 = src[i+xsize+1];
    /*
    register short* val1 = 0;
    register short* val2 = src+i-xsize; //val2 = src[i-xsize];
    register short* val3 = src+i-xsize+1; //val3 = src[i-xsize+1];
    register short* val4 = src+i-1; //val4 = src[i-1];
    register short* val5 = src+i; //val5 = src[i];
    register short* val6 = src+i+1; //val6 = src[i+1];
    register short* val7 = src+i+xsize-1; //val7 = src[i+xsize-1];
    register short* val8 = src+i+xsize; //val8 = src[i+xsize];
    register short* val9 = src+i+xsize+1; //val9 = src[i+xsize+1];*/
    //int res;
// for (i=xsize+1;i<size;i++) {
    for (k=1; k<ysize; k++) {
      for (j=1; j<xsize; j++) {
        val1 = val2;
        val2 = val3;
        val3 = src+i-xsize+1;
        val4 = val5;
        val5 = val6;
        val6 = src+i+1;
        val7 = val8;
        val8 = val9;
        val9 = src+i+xsize+1;

        /* if (i%xsize == 0 || i%xsize == xsize-1) continue;
 #ifndef __APPLE__
         for (j=0;j<3;j++)
 #else
         for (j=1;j<3;j+=2)
 #endif
         { */

        res1 = mat1*static_cast<int>(reinterpret_cast<unsigned char*>(val1)[j]);
        res2 = mat2*static_cast<int>(reinterpret_cast<unsigned char*>(val2)[j]);
        res3 = mat3*static_cast<int>(reinterpret_cast<unsigned char*>(val3)[j]);
        res4 = mat4*static_cast<int>(reinterpret_cast<unsigned char*>(val4)[j]);
        res5 = mat5*static_cast<int>(reinterpret_cast<unsigned char*>(val5)[j]);
        res6 = mat6*static_cast<int>(reinterpret_cast<unsigned char*>(val6)[j]);
        res7 = mat7*static_cast<int>(reinterpret_cast<unsigned char*>(val7)[j]);
        res8 = mat8*static_cast<int>(reinterpret_cast<unsigned char*>(val8)[j]);
        res9 = mat9*static_cast<int>(reinterpret_cast<unsigned char*>(val9)[j]);
        res1 += res2 + res3;
        res4 += res5 + res6;
        res7 += res8 + res9;
        res1 += res4 + res7;
        res1*=range;
        res1>>=16;
        // ((unsigned char*)dest)[i*2] = 128;
        // ((unsigned char*)dest)[i*2+2] = 128;
        ((unsigned char*)dest)[i*2+1] = CLAMP(res1);
        // }
        ((unsigned char*)dest)[i*2] = 128;
        // ((unsigned char*)dest)[i*2+2] = 128;
        i++;
      }
      i=k*tempImg.xsize;
    }
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  }
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#endif
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}

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//too many temps for all the registers - reuse some
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void pix_convolve :: calculate3x3YUVAltivec(imageStruct &image,imageStruct &tempImg)
{
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#ifdef __VEC__
  int h,w,width,i;
  int xsize =  (tempImg.xsize)*2;

  width = (tempImg.xsize)/8;
  //format is U Y V Y

  union {
    short   elements[8];
    vector  signed short v;
  } shortBuffer;

  union {
    unsigned int    elements[4];
    vector  unsigned int v;
  } intBuffer;

  vector unsigned char one;
  vector signed short mat1,mat2,mat3,mat4,mat5,mat6,mat7,mat8,mat9;
  vector unsigned char  val1,val2,val3,val4,val5,val6,val7,val8,val9;
  register vector signed int  res1,res2,res3,res4,res5,res6,res7,res8,res9;
  vector signed int  yhi,ylo;
  register vector signed int  res1a,res2a,res3a,res4a,res5a,res6a,res7a,res8a,res9a;
  vector unsigned int bitshift;
  register vector signed short y1,y2,y3,y4,y5,y6,y7,y8,y9,yres,uvres,hiImage,loImage;
  vector signed short range,uvnone,uv128;
  unsigned char *dst =  (unsigned char*) image.data;
  unsigned char *src =  (unsigned char*) tempImg.data;


  one =  vec_splat_u8( 1 );

  intBuffer.elements[0] = 8;
  //Load it into the vector unit
  bitshift = intBuffer.v;
  bitshift = (vector unsigned int)vec_splat((vector unsigned int)bitshift,0);

  shortBuffer.elements[0] = m_irange;
  range = shortBuffer.v;
  range = (vector signed short)vec_splat((vector signed short)range, 0);

  shortBuffer.elements[0] = 128;
  uvnone = shortBuffer.v;
  uvnone = (vector signed short)vec_splat((vector signed short)uvnone, 0);

  //load the matrix values into vectors
  shortBuffer.elements[0] = m_imatrix[0];
  mat1 = shortBuffer.v;
  mat1 = (vector signed short)vec_splat((vector signed short)mat1,0);

  shortBuffer.elements[0] = m_imatrix[1];
  mat2 = shortBuffer.v;
  mat2 = (vector signed short)vec_splat((vector signed short)mat2,0);

  shortBuffer.elements[0] = m_imatrix[2];
  mat3 = shortBuffer.v;
  mat3 = (vector signed short)vec_splat((vector signed short)mat3,0);

  shortBuffer.elements[0] = m_imatrix[3];
  mat4 = shortBuffer.v;
  mat4 = (vector signed short)vec_splat((vector signed short)mat4,0);

  shortBuffer.elements[0] = m_imatrix[4];
  mat5 = shortBuffer.v;
  mat5 = (vector signed short)vec_splat((vector signed short)mat5,0);

  shortBuffer.elements[0] = m_imatrix[5];
  mat6 = shortBuffer.v;
  mat6 = (vector signed short)vec_splat((vector signed short)mat6,0);

  shortBuffer.elements[0] = m_imatrix[6];
  mat7 = shortBuffer.v;
  mat7 = (vector signed short)vec_splat((vector signed short)mat7,0);

  shortBuffer.elements[0] = m_imatrix[7];
  mat8 = shortBuffer.v;
  mat8 = (vector signed short)vec_splat((vector signed short)mat8,0);

  shortBuffer.elements[0] = m_imatrix[8];
  mat9 = shortBuffer.v;
  mat9 = (vector signed short)vec_splat((vector signed short)mat9,0);

  shortBuffer.elements[0] = 128;
  uv128 = shortBuffer.v;
  uv128 = (vector signed short)vec_splat((vector signed short)uv128,0);
#ifndef PPC970
  UInt32                      prefetchSize = GetPrefetchConstant( 16, 1, 256 );
  vec_dst( src, prefetchSize, 0 );
  vec_dst( dst, prefetchSize, 0 );
#endif
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  i = xsize*2;
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//need to treat the first rows as a special case for accuracy and keep it from crashing
//or just skip the first 2 rows ;)
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  for ( h=2; h<image.ysize-1; h++) {
    // i+=2; //this gets rid of the echoes but kills the vertical edge-detects???
    i+=8;
    for (w=0; w<width-1; w++) {
#ifndef PPC970
      vec_dst( src, prefetchSize, 0 );
      vec_dst( dst, prefetchSize, 1 );
#endif
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      val1 = vec_ld(0,src+(i-xsize-2));//this might crash?
      val2 = vec_ld(0,src+(i-xsize));
      val3 = vec_ld(0,src+(i-xsize+2));
      val4 = vec_ld(0,src+(i-2));
      val5 = vec_ld(0,src+i);
      val6 = vec_ld(0,src+(i+2));
      val7 = vec_ld(0,src+(i+xsize-2));
      val8 = vec_ld(0,src+(i+xsize));
      val9 = vec_ld(0,src+(i+xsize+2));

      //extract the Y for processing
      y1 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val1);
      y2 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val2);
      y3 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val3);
      y4 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val4);
      y5 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val5);
      y6 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val6);
      y7 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val7);
      y8 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val8);
      y9 = (vector signed short)vec_mulo((vector unsigned char)one,(vector unsigned char)val9);

      uvres = (vector signed short)vec_mule((vector unsigned char)one,(vector unsigned char)val5);

      //mult the Y by the matrix coefficient
      res1 = vec_mulo(mat1,y1);
      res2 = vec_mulo(mat2,y2);
      res3 = vec_mulo(mat3,y3);
      res4 = vec_mulo(mat4,y4);
      res5 = vec_mulo(mat5,y5);
      res6 = vec_mulo(mat6,y6);
      res7 = vec_mulo(mat7,y7);
      res8 = vec_mulo(mat8,y8);
      res9 = vec_mulo(mat9,y9);

      res1a = vec_mule(mat1,y1);
      res2a = vec_mule(mat2,y2);
      res3a = vec_mule(mat3,y3);
      res4a = vec_mule(mat4,y4);
      res5a = vec_mule(mat5,y5);
      res6a = vec_mule(mat6,y6);
      res7a = vec_mule(mat7,y7);
      res8a = vec_mule(mat8,y8);
      res9a = vec_mule(mat9,y9);

      //sum the results - these are only 1 cycle ops so no dependency issues
      res1 = vec_adds(res1,res2); //1+2
      res3 = vec_adds(res3,res4);//3+4
      res5 = vec_adds(res5,res6);//5+6
      res7 = vec_adds(res7,res8);//7+8
      res1 = vec_adds(res1,res3);//(1+2)+(3+4)
      res7 = vec_adds(res7,res9);//7+8+9
      res1 = vec_adds(res1,res5);//(1+2)+(3+4)+(5+6)
      res1 = vec_adds(res1,res7);//(1+2)+(3+4)+(5+6)+(7+8+9)

      res1a = vec_adds(res1a,res2a); //1+2
      res3a = vec_adds(res3a,res4a);//3+4
      res5a = vec_adds(res5a,res6a);//5+6
      res7a = vec_adds(res7a,res8a);//7+8
      res1a = vec_adds(res1a,res3a);//(1+2)+(3+4)
      res7a = vec_adds(res7a,res9a);//7+8+9
      res1a = vec_adds(res1a,res5a);//(1+2)+(3+4)+(5+6)
      res1a = vec_adds(res1a,res7a);//(1+2)+(3+4)+(5+6)+(7+8+9)


      //do the bitshift on the results here??
      res1 = vec_sra(res1,bitshift);
      res1a = vec_sra(res1a,bitshift);

      //pack back to one short vector??
      yhi = vec_mergeh(res1a,res1);
      ylo = vec_mergel(res1a,res1);


      yres = vec_packs(yhi,ylo);


      //combine with the UV
      //vec_mergel + vec_mergeh Y and UV
      hiImage =  vec_mergeh(uvres,yres);
      loImage =  vec_mergel(uvres,yres);

      val1 = vec_packsu(hiImage,loImage);
      vec_st(val1,0,dst+i);
      i+=16;

    }
    i = h * xsize;
#ifndef PPC970
    vec_dss( 0 );
    vec_dss( 1 );
#endif
  }  /*end of working altivec function */
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#endif
}
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/////////////////////////////////////////////////////////
// rangeMess
//
/////////////////////////////////////////////////////////
void pix_convolve :: rangeMess(float range)
{
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  m_irange = (int)(range*255.f);
  setPixModified();
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}

/////////////////////////////////////////////////////////
// matrixMess
//
/////////////////////////////////////////////////////////
void pix_convolve :: matrixMess(int argc, t_atom *argv)
{
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  if (argc != m_cols * m_rows) {
    error("matrix size not correct");
    return;
  }
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  int i;
  for (i = 0; i < argc; i++) {
    m_imatrix[i] = (int)(atom_getfloat(&argv[i])*255.);
  }
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  setPixModified();
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}

/////////////////////////////////////////////////////////
// static member function
//
/////////////////////////////////////////////////////////
void pix_convolve :: obj_setupCallback(t_class *classPtr)
{
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  class_addmethod(classPtr, reinterpret_cast<t_method>(&pix_convolve::matrixMessCallback),
                  gensym("matrix"), A_GIMME, A_NULL);
  class_addmethod(classPtr, reinterpret_cast<t_method>(&pix_convolve::rangeMessCallback),
                  gensym("ft1"), A_FLOAT, A_NULL);
  class_addmethod(classPtr, reinterpret_cast<t_method>(&pix_convolve::chromaMessCallback),
                  gensym("chroma"), A_FLOAT, A_NULL);
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}
void pix_convolve :: matrixMessCallback(void *data, t_symbol *, int argc, t_atom *argv)
{
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  GetMyClass(data)->matrixMess(argc, argv);
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}
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void pix_convolve :: rangeMessCallback(void *data, t_float range)
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{
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  GetMyClass(data)->rangeMess(range);
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}
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void pix_convolve :: chromaMessCallback(void *data, t_float value)
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{
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  GetMyClass(data)->m_chroma=static_cast<int>(value);
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}